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Weaire–Phelan structure

May 02, 2023

Weaire–Phelan structure
Space group
Fibrifold notation
Coxeter notation		 Pm3n (223)
2o
[[4,3,4]+]

In geometry, the Weaire–Phelan structure is a three-dimensional structure representing an idealised foam of equal-sized bubbles, with two different shapes. In 1993, Denis Weaire and Robert Phelan found that this structure was a better solution of the Kelvin problem of tiling space by equal volume cells of minimum surface area than the previous best-known solution, the Kelvin structure.[1]

History and the Kelvin problem

 
The bitruncated cubic honeycomb, a convex honeycomb whose truncated octahedron cells are deformed slightly to form the Kelvin structure

In two dimensions, the subdivision of the plane into cells of equal area with minimum average perimeter is given by the hexagonal tiling, but although the first record of this honeycomb conjecture goes back to the ancient Roman scholar Marcus Terentius Varro, it was not proven until the work of Thomas C. Hales in 1999.[2] In 1887, Lord Kelvin asked the corresponding question for three-dimensional space: how can space be partitioned into cells of equal volume with the least area of surface between them? Or, in short, what was the most efficient soap bubble foam?[3] This problem has since been referred to as the Kelvin problem.

Kelvin proposed a foam called the Kelvin structure. His foam is based on the bitruncated cubic honeycomb, a convex uniform honeycomb formed by the truncated octahedron, a space-filling convex polyhedron with 6 square faces and 8 hexagonal faces. However, this honeycomb does not satisfy Plateau's laws, formulated by Joseph Plateau in the 19th century, according to which minimal foam surfaces meet at   angles at their edges, with these edges meeting each other in sets of four with angles of  . The angles of the polyhedral structure are different; for instance, its edges meet at angles of   on square faces, or   on hexagonal faces. Therefore, Kelvin's proposed structure uses curvilinear edges and slightly warped minimal surfaces for its faces, obeying Plateau's laws and reducing the area of the structure by 0.2% compared with the corresponding polyhedral structure.[1][3]

Although Kelvin did not state it explicitly as a conjecture,[4] the idea that the foam of the bitruncated cubic honeycomb is the most efficient foam, and solves Kelvin's problem, became known as the Kelvin conjecture. It was widely believed, and no counter-example was known for more than 100 years. Finally, in 1993, Trinity College Dublin physicist Denis Weaire and his student Robert Phelan discovered the Weaire–Phelan structure through computer simulations of foam, and showed that it was more efficient, disproving the Kelvin conjecture.[1]

Since the discovery of the Weaire–Phelan structure, other counterexamples to the Kelvin conjecture have been found, but the Weaire–Phelan structure continues to have the smallest known surface area per cell of these counterexamples.[5][6][7] Although numerical experiments suggest that the Weaire–Phelan structure is optimal, this remains unproven.[8] In general, it has been very difficult to prove the optimality of structures involving minimal surfaces. The minimality of the sphere as a surface enclosing a single volume was not proven until the 19th century, and the next simplest such problem, the double bubble conjecture on enclosing two volumes, remained open for over 100 years until being proven in 2002.[9]

Description

 
Irregular dodecahedron
 
Tetrakaidecahedron

The Weaire–Phelan structure differs from Kelvin's in that it uses two kinds of cells, although they have equal volume. Like the cells in Kelvin's structure, these cells are combinatorially equivalent to convex polyhedra. One is a pyritohedron, an irregular dodecahedron with pentagonal faces, possessing tetrahedral symmetry (Th). The second is a form of truncated hexagonal trapezohedron, a species of tetrakaidecahedron with two hexagonal and twelve pentagonal faces, in this case only possessing two mirror planes and a rotoreflection symmetry. Like the hexagons in the Kelvin structure, the pentagons in both types of cells are slightly curved. The surface area of the Weaire–Phelan structure is 0.3% less than that of the Kelvin structure.[1]

 
Tetrastix, modeling the face-to-face chains of tetrakaidecahedron cells in the Weaire–Phelan structure

The tetrakaidecahedron cells, linked up in face-to-face chains of cells along their hexagonal faces, form chains in three perpendicular directions. A combinatorially equivalent structure to the Weaire–Phelan structure can be made as a tiling of space by unit cubes, lined up face-to-face into infinite square prisms in the same way to form a structure of interlocking prisms called tetrastix. These prisms surround cubical voids which form one fourth of the cells of the cubical tiling; the remaining three fourths of the cells fill the prisms, offset by half a unit from the integer grid aligned with the prism walls. Similarly, in the Weaire–Phelan structure itself, which has the same symmetries as the tetrastix structure, 1/4 of the cells are dodecahedra and 3/4 are tetrakaidecahedra.[10]

The polyhedral honeycomb associated with the Weaire–Phelan structure (obtained by flattening the faces and straightening the edges) is also referred to loosely as the Weaire–Phelan structure. It was known well before the Weaire–Phelan structure was discovered, but the application to the Kelvin problem was overlooked.[11]

Applications

In physical systems

 
A close-up of the mold used for the growth of ordered liquid foams.

Experiments have shown that, with favorable boundary conditions, equal-volume bubbles spontaneously self-assemble into the Weaire–Phelan structure.[12][13]

The associated polyhedral honeycomb is found in two related geometries of crystal structure in chemistry. Where the components of the crystal lie at the centres of the polyhedra it forms one of the Frank–Kasper phases, the A15 phase.[14]

Where the components of the crystal lie at the corners of the polyhedra, it is known as the "Type I clathrate structure". Gas hydrates formed by methane, propane and carbon dioxide at low temperatures have a structure in which water molecules lie at the nodes of the Weaire–Phelan structure and are hydrogen bonded together, and the larger gas molecules are trapped in the polyhedral cages.[11] Some alkali metal hydrides silicides and germanides also form this structure, with silicon or germanium at nodes, and alkali metals in cages.[1][15][16]

In architecture

The Weaire–Phelan structure is the inspiration for the design by Tristram Carfrae of the Beijing National Aquatics Centre, the 'Water Cube', for the 2008 Summer Olympics.[17]

See also

References

  1. ^ a b c d e Weaire, D.; Phelan, R. (1994), "A counter-example to Kelvin's conjecture on minimal surfaces", Phil. Mag. Lett., 69 (2): 107–110, Bibcode:1994PMagL..69..107W, doi:10.1080/09500839408241577.
  2. ^ Hales, T. C. (2001), "The honeycomb conjecture", Discrete & Computational Geometry, 25 (1): 1–22, doi:10.1007/s004540010071, MR 1797293
  3. ^ a b Lord Kelvin (Sir William Thomson) (1887), "On the Division of Space with Minimum Partitional Area" (PDF), Philosophical Magazine, 24 (151): 503, doi:10.1080/14786448708628135.
  4. ^ Weaire & Phelan (1994) write that it is "implicit rather than directly stated in Kelvin's original papers"
  5. ^ Sullivan, John M. (1999), "The geometry of bubbles and foams", Foams and emulsions (Cargèse, 1997), NATO Advanced Science Institutes Series E: Applied Sciences, vol. 354, Kluwer, pp. 379–402, MR 1688327
  6. ^ Gabbrielli, Ruggero (1 August 2009), "A new counter-example to Kelvin's conjecture on minimal surfaces", Philosophical Magazine Letters, 89 (8): 483–491, Bibcode:2009PMagL..89..483G, doi:10.1080/09500830903022651, ISSN 0950-0839, S2CID 137653272
  7. ^ Freiberger, Marianne (24 September 2009), "Kelvin's bubble burst again", Plus Magazine, University of Cambridge, retrieved 4 July 2017
  8. ^ Oudet, Édouard (2011), "Approximation of partitions of least perimeter by Γ-convergence: around Kelvin's conjecture", Experimental Mathematics, 20 (3): 260–270, doi:10.1080/10586458.2011.565233, MR 2836251, S2CID 2945749
  9. ^ Morgan, Frank (2009), "Chapter 14. Proof of Double Bubble Conjecture", Geometric Measure Theory: A Beginner's Guide (4th ed.), Academic Press.
  10. ^ Conway, John H.; Burgiel, Heidi; Goodman-Strauss, Chaim (2008), "Understanding the Irish Bubbles", The Symmetries of Things, Wellesley, Massachusetts: A K Peters, p. 351, ISBN 978-1-56881-220-5, MR 2410150
  11. ^ a b Pauling, Linus (1960), The Nature of the Chemical Bond (3rd ed.), Cornell University Press, p. 471
  12. ^ Gabbrielli, R.; Meagher, A.J.; Weaire, D.; Brakke, K.A.; Hutzler, S. (2012), "An experimental realization of the Weaire-Phelan structure in monodisperse liquid foam" (PDF), Phil. Mag. Lett., 92 (1): 1–6, Bibcode:2012PMagL..92....1G, doi:10.1080/09500839.2011.645898, S2CID 25427974.
  13. ^ Ball, Philip (2011), "Scientists make the 'perfect' foam: Theoretical low-energy foam made for real", Nature, doi:10.1038/nature.2011.9504, S2CID 136626668.
  14. ^ Frank, F. C.; Kasper, J. S. (1958), "Complex alloy structures regarded as sphere packings. I. Definitions and basic principles" (PDF), Acta Crystallogr., 11 (3): 184–190, doi:10.1107/s0365110x58000487. Frank, F. C.; Kasper, J. S. (1959), "Complex alloy structures regarded as sphere packings. II. Analysis and classification of representative structures", Acta Crystallogr., 12 (7): 483–499, doi:10.1107/s0365110x59001499.
  15. ^ Kasper, J. S.; Hagenmuller, P.; Pouchard, M.; Cros, C. (December 1965), "Clathrate structure of silicon Na8Si46 and NaxSi136 (x < 11)", Science, 150 (3704): 1713–1714, Bibcode:1965Sci...150.1713K, doi:10.1126/science.150.3704.1713, PMID 17768869, S2CID 21291705
  16. ^ Cros, Christian; Pouchard, Michel; Hagenmuller, Paul (December 1970), "Sur une nouvelle famille de clathrates minéraux isotypes des hydrates de gaz et de liquides, interprétation des résultats obtenus", Journal of Solid State Chemistry, 2 (4): 570–581, Bibcode:1970JSSCh...2..570C, doi:10.1016/0022-4596(70)90053-8
  17. ^ Fountain, Henry (August 5, 2008), "A Problem of Bubbles Frames an Olympic Design", New York Times

External links

  • Weaire–Phelan Bubbles page with illustrations and freely downloadable 'nets' for printing and making models.
  • "Weaire-Phelan Smart Modular Space Settlement", Alexandru Pintea, 2017, Individual First Prize

May 02, 2023
weaire, phelan, structure, space, groupfibrifold, notationcoxeter, notation, geometry, three, dimensional, structure, representing, idealised, foam, equal, sized, bubbles, with, different, shapes, 1993, denis, weaire, robert, phelan, found, that, this, structu. Weaire Phelan structureSpace groupFibrifold notationCoxeter notation Pm3 n 223 2o 4 3 4 In geometry the Weaire Phelan structure is a three dimensional structure representing an idealised foam of equal sized bubbles with two different shapes In 1993 Denis Weaire and Robert Phelan found that this structure was a better solution of the Kelvin problem of tiling space by equal volume cells of minimum surface area than the previous best known solution the Kelvin structure 1 Contents 1 History and the Kelvin problem 2 Description 3 Applications 3 1 In physical systems 3 2 In architecture 4 See also 5 References 6 External linksHistory and the Kelvin problem Edit The bitruncated cubic honeycomb a convex honeycomb whose truncated octahedron cells are deformed slightly to form the Kelvin structure In two dimensions the subdivision of the plane into cells of equal area with minimum average perimeter is given by the hexagonal tiling but although the first record of this honeycomb conjecture goes back to the ancient Roman scholar Marcus Terentius Varro it was not proven until the work of Thomas C Hales in 1999 2 In 1887 Lord Kelvin asked the corresponding question for three dimensional space how can space be partitioned into cells of equal volume with the least area of surface between them Or in short what was the most efficient soap bubble foam 3 This problem has since been referred to as the Kelvin problem Kelvin proposed a foam called the Kelvin structure His foam is based on the bitruncated cubic honeycomb a convex uniform honeycomb formed by the truncated octahedron a space filling convex polyhedron with 6 square faces and 8 hexagonal faces However this honeycomb does not satisfy Plateau s laws formulated by Joseph Plateau in the 19th century according to which minimal foam surfaces meet at 120 displaystyle 120 circ angles at their edges with these edges meeting each other in sets of four with angles of arccos 1 3 109 47 displaystyle arccos tfrac 1 3 approx 109 47 circ The angles of the polyhedral structure are different for instance its edges meet at angles of 90 displaystyle 90 circ on square faces or 120 displaystyle 120 circ on hexagonal faces Therefore Kelvin s proposed structure uses curvilinear edges and slightly warped minimal surfaces for its faces obeying Plateau s laws and reducing the area of the structure by 0 2 compared with the corresponding polyhedral structure 1 3 Although Kelvin did not state it explicitly as a conjecture 4 the idea that the foam of the bitruncated cubic honeycomb is the most efficient foam and solves Kelvin s problem became known as the Kelvin conjecture It was widely believed and no counter example was known for more than 100 years Finally in 1993 Trinity College Dublin physicist Denis Weaire and his student Robert Phelan discovered the Weaire Phelan structure through computer simulations of foam and showed that it was more efficient disproving the Kelvin conjecture 1 Since the discovery of the Weaire Phelan structure other counterexamples to the Kelvin conjecture have been found but the Weaire Phelan structure continues to have the smallest known surface area per cell of these counterexamples 5 6 7 Although numerical experiments suggest that the Weaire Phelan structure is optimal this remains unproven 8 In general it has been very difficult to prove the optimality of structures involving minimal surfaces The minimality of the sphere as a surface enclosing a single volume was not proven until the 19th century and the next simplest such problem the double bubble conjecture on enclosing two volumes remained open for over 100 years until being proven in 2002 9 Description Edit Irregular dodecahedron Tetrakaidecahedron The Weaire Phelan structure differs from Kelvin s in that it uses two kinds of cells although they have equal volume Like the cells in Kelvin s structure these cells are combinatorially equivalent to convex polyhedra One is a pyritohedron an irregular dodecahedron with pentagonal faces possessing tetrahedral symmetry Th The second is a form of truncated hexagonal trapezohedron a species of tetrakaidecahedron with two hexagonal and twelve pentagonal faces in this case only possessing two mirror planes and a rotoreflection symmetry Like the hexagons in the Kelvin structure the pentagons in both types of cells are slightly curved The surface area of the Weaire Phelan structure is 0 3 less than that of the Kelvin structure 1 Tetrastix modeling the face to face chains of tetrakaidecahedron cells in the Weaire Phelan structure The tetrakaidecahedron cells linked up in face to face chains of cells along their hexagonal faces form chains in three perpendicular directions A combinatorially equivalent structure to the Weaire Phelan structure can be made as a tiling of space by unit cubes lined up face to face into infinite square prisms in the same way to form a structure of interlocking prisms called tetrastix These prisms surround cubical voids which form one fourth of the cells of the cubical tiling the remaining three fourths of the cells fill the prisms offset by half a unit from the integer grid aligned with the prism walls Similarly in the Weaire Phelan structure itself which has the same symmetries as the tetrastix structure 1 4 of the cells are dodecahedra and 3 4 are tetrakaidecahedra 10 The polyhedral honeycomb associated with the Weaire Phelan structure obtained by flattening the faces and straightening the edges is also referred to loosely as the Weaire Phelan structure It was known well before the Weaire Phelan structure was discovered but the application to the Kelvin problem was overlooked 11 Applications EditIn physical systems Edit A close up of the mold used for the growth of ordered liquid foams Experiments have shown that with favorable boundary conditions equal volume bubbles spontaneously self assemble into the Weaire Phelan structure 12 13 The associated polyhedral honeycomb is found in two related geometries of crystal structure in chemistry Where the components of the crystal lie at the centres of the polyhedra it forms one of the Frank Kasper phases the A15 phase 14 Where the components of the crystal lie at the corners of the polyhedra it is known as the Type I clathrate structure Gas hydrates formed by methane propane and carbon dioxide at low temperatures have a structure in which water molecules lie at the nodes of the Weaire Phelan structure and are hydrogen bonded together and the larger gas molecules are trapped in the polyhedral cages 11 Some alkali metal hydrides silicides and germanides also form this structure with silicon or germanium at nodes and alkali metals in cages 1 15 16 In architecture Edit Beijing National Aquatics Centre The Weaire Phelan structure is the inspiration for the design by Tristram Carfrae of the Beijing National Aquatics Centre the Water Cube for the 2008 Summer Olympics 17 See also EditThe Pursuit of Perfect Packing a book by Weaire on this and related problemsReferences Edit a b c d e Weaire D Phelan R 1994 A counter example to Kelvin s conjecture on minimal surfaces Phil Mag Lett 69 2 107 110 Bibcode 1994PMagL 69 107W doi 10 1080 09500839408241577 Hales T C 2001 The honeycomb conjecture Discrete amp Computational Geometry 25 1 1 22 doi 10 1007 s004540010071 MR 1797293 a b Lord Kelvin Sir William Thomson 1887 On the Division of Space with Minimum Partitional Area PDF Philosophical Magazine 24 151 503 doi 10 1080 14786448708628135 Weaire amp Phelan 1994 write that it is implicit rather than directly stated in Kelvin s original papers Sullivan John M 1999 The geometry of bubbles and foams Foams and emulsions Cargese 1997 NATO Advanced Science Institutes Series E Applied Sciences vol 354 Kluwer pp 379 402 MR 1688327 Gabbrielli Ruggero 1 August 2009 A new counter example to Kelvin s conjecture on minimal surfaces Philosophical Magazine Letters 89 8 483 491 Bibcode 2009PMagL 89 483G doi 10 1080 09500830903022651 ISSN 0950 0839 S2CID 137653272 Freiberger Marianne 24 September 2009 Kelvin s bubble burst again Plus Magazine University of Cambridge retrieved 4 July 2017 Oudet Edouard 2011 Approximation of partitions of least perimeter by G convergence around Kelvin s conjecture Experimental Mathematics 20 3 260 270 doi 10 1080 10586458 2011 565233 MR 2836251 S2CID 2945749 Morgan Frank 2009 Chapter 14 Proof of Double Bubble Conjecture Geometric Measure Theory A Beginner s Guide 4th ed Academic Press Conway John H Burgiel Heidi Goodman Strauss Chaim 2008 Understanding the Irish Bubbles The Symmetries of Things Wellesley Massachusetts A K Peters p 351 ISBN 978 1 56881 220 5 MR 2410150 a b Pauling Linus 1960 The Nature of the Chemical Bond 3rd ed Cornell University Press p 471 Gabbrielli R Meagher A J Weaire D Brakke K A Hutzler S 2012 An experimental realization of the Weaire Phelan structure in monodisperse liquid foam PDF Phil Mag Lett 92 1 1 6 Bibcode 2012PMagL 92 1G doi 10 1080 09500839 2011 645898 S2CID 25427974 Ball Philip 2011 Scientists make the perfect foam Theoretical low energy foam made for real Nature doi 10 1038 nature 2011 9504 S2CID 136626668 Frank F C Kasper J S 1958 Complex alloy structures regarded as sphere packings I Definitions and basic principles PDF Acta Crystallogr 11 3 184 190 doi 10 1107 s0365110x58000487 Frank F C Kasper J S 1959 Complex alloy structures regarded as sphere packings II Analysis and classification of representative structures Acta Crystallogr 12 7 483 499 doi 10 1107 s0365110x59001499 Kasper J S Hagenmuller P Pouchard M Cros C December 1965 Clathrate structure of silicon Na8Si46 and NaxSi136 x lt 11 Science 150 3704 1713 1714 Bibcode 1965Sci 150 1713K doi 10 1126 science 150 3704 1713 PMID 17768869 S2CID 21291705 Cros Christian Pouchard Michel Hagenmuller Paul December 1970 Sur une nouvelle famille de clathrates mineraux isotypes des hydrates de gaz et de liquides interpretation des resultats obtenus Journal of Solid State Chemistry 2 4 570 581 Bibcode 1970JSSCh 2 570C doi 10 1016 0022 4596 70 90053 8 Fountain Henry August 5 2008 A Problem of Bubbles Frames an Olympic Design New York TimesExternal links Edit3D models of the Weaire Phelan Kelvin and P42a structures Weaire Phelan Bubbles page with illustrations and freely downloadable nets for printing and making models Weaire Phelan Smart Modular Space Settlement Alexandru Pintea 2017 Individual First Prize NASA Ames Space Settlement Contest Retrieved from https en wikipedia org w index php title Weaire Phelan structure amp oldid 1108655522, wikipedia, wiki, book, books, library,

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